雙向地震下非對稱房屋結構的黏彈塑性分析

陳政源; Cheng-Yuan Chen

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/94087

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	劉立偉	zh_TW
dc.contributor.advisor	Li-Wei Liu	en
dc.contributor.author	陳政源	zh_TW
dc.contributor.author	Cheng-Yuan Chen	en
dc.date.accessioned	2024-08-14T16:37:32Z	-
dc.date.available	2024-08-15	-
dc.date.copyright	2024-08-14	-
dc.date.issued	2024	-
dc.date.submitted	2024-08-10	-
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/94087	-
dc.description.abstract	本研究旨在研究房屋結構在雙向地震作用下的受震反應，提出了一個非對稱房屋結構的黏彈塑性模式以分析其受震反應，此模式考慮兩向層間剪力（位移）與扭矩（扭角）的關係，包含：各向勁度不對稱、走動硬軟化、非等向降伏面與阻尼現象。為了要能夠精確計算出房屋結構的地震反應歷時，本研究使用狀態空間表示法，根據精確的判斷準則，將複雜的黏彈塑性動態系統細分為一個彈性項與多個塑性相動態系統，接著再針對每一相求解對應的房屋結構動態反應。本研究發現，在有樓層進入塑性態時，可以再進一步將計算塑性相動態系統反應分解成：先計算樓層塑性內變數，再計算整棟房屋的動態反應；並且發現模式具有李群（Lie group）和李代數(Lie algebra)的內在對稱性，因此可推得塑性內變數單步解析解，進而獲得整棟房屋的動態反應單步解析解。此計算方法也經由誤差分析，驗證其精確性。接下來，本研究根據提出之非對稱房屋結構黏彈塑性模式，考慮921集集地震事件全台灣所有地震測站歷時，分析房屋結構其受震後的反應。先以原始地震歷時分析比較單向地震分析及雙向地震分析之反應；接著經由計算出全台灣地震測站歷時所得之房屋塑性當量圖，以分析房屋結構的塑性損傷。此外，也進行地震力入射角對於房屋結構反應的影響；並且進行最大地表加速度分析探討房屋結構隨著譜加速度增加，其速度脈衝型地震與非速度脈衝型地震作用下的反應。研究結果顯示，房屋結構若以單向地震分析，確實相較雙向地震力分析有錯估的情勢；並且使用單向地震力分析建築結構時其塑性損傷會嚴重的低估，其總層間位移反應及總層間剪力反應平均來看也是相對低估，由此可知以雙向水平地震分析更能貼近房屋結構的受震情況。再者，經由地震力入射角分析也可以看出非對稱房屋對於地震力入射角之考量有一定的影響。此外，非對稱房屋結構經由最大地表加速度分析，顯示某些速度脈衝地震確實造成較大的房屋結構反應。	zh_TW
dc.description.abstract	This study aims to investigate the seismic response of asymmetric building structures under bidirectional earthquake excitations. A viscoelastoplastic model of the building structures is proposed taking into account an anisotropic stiffness between the interstory two-directional shears, torque and the interstory two-directional displacement and rotation; a anisotropic yield surface; kinematic hardening and softening; and the damping effects. To accurately calculate the time history of seismic responses for asymmetric building structures, the conventional formulation of the model is rearranged; the state-space representation approach is employed; and the internal symmetry of the model is explored in this study. According to careful derivation about the switching of the plastic mechanism, the complex viscoelastoplastic dynamical system is decomposed into an viscoelastic phase and multiple viscoelastoplastic phases, and then the dynamical responses of the building structure for each part are solved separately. In each viscoelastoplastic phase, the response of the building is decomposed into two steps including the calculation of the plastic internal variables based on the internal symmetry, and then determinate of the total responses via the state-space representation. Since the internal symmetry of the Lie group SO(3,1) and the Lie algebra so(3,1), provides the closed-form solution for the plastic internal variables in each single step, and consequently the closed-form response of the building structure in each single step is obtained. The accuracy of this calculation method is also verified through error analysis. Next, based on the proposed viscoelastoplastic model for asymmetric building structures and considering the ground motion time histories recorded at all seismic stations in Taiwan during the 1999 Chi-Chi earthquake event, the seismic responses of building structures were analyzed. First, the original ground motion time histories were used to compare the responses from unidirectional and bidirectional seismic analyses. Then, the plastic ductility demand contours for building structures in Taiwan were computed from the recorded ground motions to assess the plastic damage. Furthermore, the influence of the incidence angle of seismic excitations on the structural responses was investigated. A peak ground acceleration analysis was also performed to study the responses of building structures under velocity pulse-like and non-velocity pulse-like earthquakes as the peak ground acceleration increases. The results show that if building structures are analyzed using unidirectional seismic excitations, their responses would indeed be underestimated compared to those from bidirectional seismic analyses. The plastic damage would be severely underestimated when using unidirectional seismic analysis, and the total interstory drift and shear responses would also be underestimated on average. This indicates that bidirectional horizontal seismic analysis can better capture the actual seismic responses of building structures. Additionally, the analysis of the incidence angle of seismic excitations also reveals that the consideration of incidence angles has a certain influence on the responses of asymmetric building structures. Moreover, the peak ground acceleration analysis for asymmetric building structures shows that some velocity pulse-like earthquakes indeed cause larger structural responses.	en
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dc.description.tableofcontents	Contents Acknowledgements i 摘要 iii Abstract v Contents ix List of Figures xv List of Tables xxvii Denotation xxix Chapter 1 Introduction 1 1.1 Motivation and objectives 1 1.2 Literature review 3 1.2.1 General seismic analysis tools 3 1.2.2 Simplified analysis methods 3 1.2.3 Simplified model considering precise plastic behavior 4 1.2.4 State-space representation 6 1.2.5 Seismic analysis method 7 1.2.6 Unidirectional seismic analysis and bidirectional seismic analysis 8 1.2.7 Effect of incident angle of seismic force 9 1.2.8 Influence of peak ground acceleration 10 1.3 Outlines 11 Chapter 2 Mathematical modeling on symmetric building structure 13 2.1 Bilinear viscoelastoplastic of a single-story in symmetric building structures 13 2.2 The straining conditions and the sufficient and necessary conditions for the viscoelastoplastic model 17 2.3 Two-phase dynamicalal systems 19 2.3.1 Viscoelastic-phase (off-phase) 21 2.3.2 Viscoelastoplastic-phase (on-phase) 21 2.4 Numertical integration based on internal symmetry 22 2.4.1 Internal symmetry in Minkowski spacetime 23 2.5 State-space representation 27 2.5.1 Viscoelastic-phase 28 2.5.2 Viscoelastoplastic-phase 30 2.6 Incremental analysis method 32 2.6.1 Linear time-invariant (LTI) system 34 2.6.2 Viscoelastic-phase module 35 2.6.3 Viscoelastoplastic-phase module 36 2.6.4 Viscoelastoplastic pull-back module 36 2.7 Algorithm 37 Chapter 3 Seismic behavior of symmetric building structures 41 3.1 Complementary trio checking of symmetric structures 42 3.2 Responses of the symmetric building structure under bidirectional and unidirectional earthquake excitations 65 3.2.1 Approximate analysis of symmetric building structures under unidirectional earthquake 65 3.2.2 Accurate analysis of symmetric building structures under bidirectional earthquake 67 3.2.3 Comparisons of unidirectional and bidirectional analysis for symmetric building structures 69 3.3 The plastic equivalent of Taiwan under the 921 Chi-Chi earthquake event 74 3.3.1 CPU time for viscoelastoplastic analysis of symmetric building structures 77 3.4 Analysis of incident angle of seismic excitations on symmetric building structures 78 3.4.1 Biunidirectional uncoupled analysis of symmetric building structures 79 3.4.2 Bidirectional coupled analysis of symmetric building structures 80 3.4.3 Comparisons of biunidirectional uncoupled (BUU) analysis and bidirectional coupled (BDC) analysis for symmetric building structures 82 3.5 Influence of seismic peak ground acceleration for symmetric building structures 88 Chapter 4 Mathematical modeling on asymmetric building structure 101 4.1 Bilinear viscoelastoplastic of a single-story in asymmetric building structures 101 4.2 The straining conditions and the sufficient and necessary conditions for the viscoelastoplastic model 106 4.3 Two-phase dynamicalal systems 108 4.3.1 Viscoelastic-phase (off-phase) 109 4.3.2 Viscoelastoplastic-phase (on-phase) 110 4.4 Numertical integration based on internal symmetry 110 4.4.1 Internal symmetry in Minkowski spacetime 111 4.5 State-space representation 115 4.5.1 Viscoelastic-phase 116 4.5.2 Viscoelastoplastic-phase 118 4.6 Incremental analysis method 120 4.6.1 Linear time-invariant (LTI) system 122 4.6.2 Viscoelastic-phase module 123 4.6.3 Viscoelastoplastic-phase module 124 4.6.4 Viscoelastoplastic pull-back module 124 4.7 Algorithm 125 Chapter 5 Seismic behavior of asymmetric building structures 129 5.1 Complementary trio checking of asymmetric structures 131 5.2 Responses of the asymmetric building structures under earthquake excitations 153 5.2.1 Approximate analysis of asymmetric building structures under unidirectional earthquake 153 5.2.2 Accurate analysis of asymmetric building structures under bidirectional earthquake 155 5.2.3 Comparisons of unidirectional and bidirectional analysis for asymmetric building structures 157 5.3 The plastic equivalent of Taiwan under the 921 Chi-Chi earthquake event 162 5.3.1 CPU time for viscoelastoplastic analysis of asymmetric building structures 166 5.4 Analysis of incident angle of seismic excitations on asymmetric building structures 167 5.4.1 Biunidirectional uncoupled analysis of asymmetric building structures 168 5.4.2 Bidirectional coupled analysis of asymmetric building structures 169 5.4.3 Comparisons of biunidirectional uncoupled (BUU) analysis and bidirectional coupled (BDC) analysis for asymmetric building structures 171 5.5 Influence of seismic peak ground acceleration for asymmetric building structures 177 Chapter 6 Conclusions and future works 191 6.1 Conclusions 191 6.2 Future work 194 References 197 Appendix A — Viscoelastoplastic analysis of multi-story asymmetric building structures 205 A.1 Bilinear viscoelastoplastic of a multi-story in asymmetric building structures 205 A.2 The straining conditions and the sufficient and necessary conditions for the ith story viscoelastoplastic model 210 A.3 Numertical integration based on internal symmetry 212 A.3.1 Internal symmetry in Minkowski spacetime 212 A.4 Total state-space representation 216 A.4.1 The ith story is viscoelastic-phase system 217 A.4.2 The ith story is viscoelastoplastic-phase system 218	-
dc.language.iso	en	-
dc.subject	非對稱建築結構	zh_TW
dc.subject	黏彈塑性	zh_TW
dc.subject	雙向地震	zh_TW
dc.subject	內部對稱性	zh_TW
dc.subject	Asymmetric building structures	en
dc.subject	Internal symmetry	en
dc.subject	Bidirectional earthquakes	en
dc.subject	Viscoelastoplastic	en
dc.title	雙向地震下非對稱房屋結構的黏彈塑性分析	zh_TW
dc.title	Viscoelastoplastic analysis of asymmetric building structures under bidirectional seismic excitation	en
dc.type	Thesis	-
dc.date.schoolyear	112-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	蔡克銓;張家銘;陳東陽	zh_TW
dc.contributor.oralexamcommittee	Keh-Chyuan Tsai;Chia-Ming Chang;Tung-Yang Chen	en
dc.subject.keyword	非對稱建築結構,黏彈塑性,雙向地震,內部對稱性,	zh_TW
dc.subject.keyword	Asymmetric building structures,Viscoelastoplastic,Bidirectional earthquakes,Internal symmetry,	en
dc.relation.page	219	-
dc.identifier.doi	10.6342/NTU202402645	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2024-08-13	-
dc.contributor.author-college	工學院	-
dc.contributor.author-dept	土木工程學系	-
顯示於系所單位：	土木工程學系

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